Viability and stress protection of chronic lymphoid leukemia cells involves overactivation of mitochondrial phosphoSTAT3Ser 727

International audienceChronic lymphoid leukemia (CLL) is characterized by the accumulation of functionally defective CD5-positive B lymphocytes. The clinical course of CLL is highly variable, ranging from a long-lasting indolent disease to an unpredictable and rapidly progressing leukemia requiring treatment. It is thus important to identify novel factors that reflect disease progression or contribute to its assessment. Here, we report on a novel STAT3-mediated pathway that characterizes CLL B cells-extended viability and oxidative stress control. We observed that leukemic but not normal B cells from CLL patients exhibit constitutive activation of an atypical form of the STAT3 signaling factor, phosphorylated on serine 727 (Ser 727) in the absence of detectable canonical tyrosine 705 (Tyr 705)-dependent activation in vivo. The Ser 727 -phosphorylated STAT3 molecule (pSTAT3Ser 727) is localized to the mitochondria and associates with complex I of the respiratory chain. This pSer 727 modification is further controlled by glutathione-dependent antioxidant pathway(s) that mediate stromal protection of the leukemic B cells and regulate their viability. Importantly, pSTAT3Ser 727 , but neither Tyr705-phosphorylated STAT3 nor total STAT3, levels correlate with prolonged in vivo CLL B cells survival. Furthermore, STAT3 activity contributes to the resistance to apoptosis of CLL, but not normal B cells, in vitro. These data reveal that mitochondrial (Mt) pSTAT3Ser 727 overactivity is part of the antioxidant defense pathway of CLL B cells that regulates their viability. Mt pSTAT3Ser 727 appears to be a newly identified cell-protective signal involved in CLL cells survival. Targeting pSTAT3Ser 727 could be a promising new therapeutic approach

STAT5-and hypoxia-dependent upregulation of AXL

Internal tandem duplication in Fms-like tyrosine kinase 3 (FLT3-ITD) is the most frequent mutation observed in acute myeloid leukemia (AML) and correlates with poor prognosis. FLT3 tyrosine kinase inhibitors are promising for targeted therapy. Here, we investigated mechanisms dampening the response to the FLT3 inhibitor quizartinib, which is specific to the hematopoietic niche. Using AML primary samples and cell lines, we demonstrate that convergent signals from the hematopoietic microenvironment drive FLT3-ITD cell resistance to quizartinib through the expression and activation of the tyrosine kinase receptor AXL. Indeed, cytokines sustained phosphorylation of the transcription factor STAT5 in quizartinib-treated cells, which enhanced AXL expression by direct binding of a conserved motif in its genomic sequence. Likewise, hypoxia, another well-known hematopoietic niche hallmark, also enhanced AXL expression. Finally, in a xenograft mouse model, inhibition of AXL significantly increased the response of FLT3-ITD cells to quizartinib exclusively within a bone marrow environment. These data highlight a new bypass mechanism specific to the hematopoietic niche that hampers the response to quizartinib through combined upregulation of AXL activity. Targeting this signaling offers the prospect of a new therapy to eradicate resistant FLT3-ITD leukemic cells hidden within their specific microenvironment, thereby preventing relapses from FLT3-ITD clones

Nouveaux rôles des facteurs STAT5 dans le maintien des cellules de leucémie myéloïde chronique

The Chronic Myeloid Leukemia (CML) is a clonal hematopoietic stem cell disorder characterized by the t(9:22) genetic translocation and expression of the oncogenic tyrosine kinase BCR-ABL . A first BCR-ABL Tyrosine Kinase Inhibitor (TKI), Imatinib (IM), was identified that inhibits proliferation of BCR-ABL expressing hematopoietic cells and leads to disease remission. However, BCR-ABL mRNA remains detectable in the most immature HSCs and discontinuation of IM results in clinical relapse. STAT5 factors play a crucial role in the CML pathogenesis of human primary CML cells. However, the contribution of the two related STAT5 genes, STAT5A and STAT5B, was unknown. We used an RNAinterference based strategy to analyze STAT5A or STAT5B roles in normal and CML cells. We showed that STAT5A/5B double knock-down (KD) triggers normal and CML cell apoptosis and suppressed long-term clonogenic potential of immature hematopoietic stem and progenitor cells known to be resistant to TKI treatment and responsible for residual disease. STAT5A loss alone was ineffective at impairing growth of both normal and CML cells under standard conditions. In contrast, STAT5A loss was sufficient to enhance Reactive Oxygen Species (ROS) which correlated with enhanced DNA damages in both normal and leukemic cells. We reported that STAT5A regulates oxidative stress through unconventional mechanisms, in a non-transcriptional-dependent manner. We further showed that, in contrast to primary cells at diagnosis, IM-resistant cells exhibited enhanced STAT5A dependence, by being sensitive to STAT5A single KD. To investigate the molecular basis of STAT5A activity in TKI-resistance and oxidative stress, we performed a transcriptomic analysis of STAT5 regulated genes. We identified Axl, which encodes a receptor tyrosine kinase, recently shown to be crucial in TKI-resistant CML cells. Specifically, Axl expression is enhanced by STAT5A. We investigated the role of Axl and we found that Axl KD did not affect survival of IM-sensitive CML cells. However, Axl KD decreased survival of IM-resistant cells, miming the activity of STAT5A. Moreover, Axl loss increased ROS levels in CML cells, promoting STAT5A anti-oxidant activity. We further sought to determine the expression of the Axl ligand, Gas6. Gas6 expression is dramatically reduced in CML primary cells at diagnosis compared to healthy cells. The strong and consistent down-regulation of Gas6 in CML cells suggested a possible role in the pathophysiology. Collectively, our findings highlight the pro-survival, stress protection and drug resistance roles of STAT5 factors, providing new understanding for medical treatment of CML patients. We suggest that STAT5A acts in synergy with Axl to face exogenous insults and propose a new mechanism by which CML cells increase their proliferation and reduce their motility by down-regulating Gas6 expression.La leucémie myéloïde chronique (LMC) est une pathologie de la cellule souche hématopoïétique caractérisée par la présence de la translocation chromosomique t(9 :22) conduisant à l’expression de la kinase BCR-ABL responsable de la maladie. Un inhibiteur de l’activité de BCR-ABL a été identifié, l’Imatinib (IM). L’IM a révolutionné la prise en charge de la LMC en bloquant sélectivement la croissance des cellules tumorales, conduisant à la rémission des patients. Cependant, une majorité d’entre eux subissent des récidives en cas d’arrêt du traitement, et environ 15% développent des résistances à l’inhibiteur. BCR-ABL active de multiples voies de signalisation parmi lesquelles figurent les facteurs de signalisation STAT5. Nous avons analysé les rôles respectives des deux facteurs STAT5, STAT5A et STAT5B, dans les cellules souches hématopoïétiques normales et de LMC, par une approche d’ARN interférence. Nos observations indiquent que l’activité des deux facteurs STAT5 permet la survie et le maintien à long terme des cellules souches de patients LMC au diagnostic. Nous avons de plus montré qu’indépendamment de son activité transcriptionnelle, STAT5A aide les cellules normales et leucémiques à limiter leur stress oxydatif. Nous avons aussi pu observer que les cellules de patients présentant des résistances secondaires à l’IM, sans mutations ni surexpression de BCR-ABL, manifestent une dépendance caractéristique vis-à-vis de l’activité STAT5A. Pour mieux comprendre les mécanismes d’action des facteurs STAT5, nous avons recherché les gènes cibles de STAT5 par une approche transcriptomique et avons identifié le récepteur tyrosine kinase Axl dont l’expression est augmentée par STAT5A. L’inhibition d’Axl dans les cellules LMC sensibles à l’IM n’a aucun effet sur leur survie, alors qu’elle diminue fortement la survie des cellules LMC résistantes à l’IM. De plus, Axl contrôle le niveau des réactifs oxygénés dans les cellules de patients LMC. Nous avons analysé l’expression d’un des activateurs d’Axl, le ligand Gas6, et avons observé que son expression diminue fortement dans les cellules primaires de LMC par rapport aux contrôles sains. Ces résultats suggèrent que le tandem Gas6/Axl pourrait participer au processus leucémique de la LMC à différents niveaux. De manière globale, nos travaux montrent que les facteurs STAT5 favorisent le maintien des cellules souches de LMC, leur résistance au stress oxydatif et aux traitements thérapeutiques Ces deux dernières activités sont au moins en partie liées à l’activité d’une nouvelle cible de STAT5, le récepteur Axl, par ailleurs déjà impliqué dans la résistance aux traitements thérapeutiques. Les facteurs STAT5 représentent donc des nouvelles cibles thérapeutiques potentielles dans l’éradication de la maladie résiduelle